GAP 4.8.9 installation with standard packages -- copy to your CoCalc project to get it
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%1%%2%W intro.tex GAP documentation D�rte Feichtenschlager3%%4%H $Id: intro.tex, v0.5 2010/05/31 09:30:00 gap SymbCompCC $5%%67%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%8\Chapter{Introduction}910%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%11\Section{Overview}1213The coclass of a finite $p$-group of order $p^n$ and nilpotency class $c$ is14defined as $n-c$. This invariant of finite $p$-groups has been introduced by15Leedham-Green and Newman in \cite{LGN80} and it became of major importance16in $p$-group theory.1718A first tool in the classification of all $p$-groups of coclass $r$ is the19coclass graph $G(p,r)$. Its vertices are the isomorphism types of finite20$p$-groups of coclass $r$. Two vertices $G$ and $H$ are joined by an edge if21$G$ is isomorphic to the quotient $H/\gamma(H)$ where $\gamma(H)$ is the last22non-trivial term of the lower series of $H$.2324Du Sautoy \cite{dS00} and Eick and Leedham-Green \cite{ELG08} proved that25$G(p,r)$ contains certain periodic patterns. Eick and Leedham-Green26\cite{ELG08} define infinite coclass sequences of finite $p$-groups of27coclass $r$ which underpin this periodic pattern. In $G(2,r)$ and $G(3,1)$28almost all groups are contained in an infinite coclass sequence.2930Eick and Leedham-Green \cite{ELG08} also proved that the infinitely many31$p$-groups in an infinite coclass sequence can be defined by a single32parametrised presentation.3334The first aim of this package is the definition of polycyclic parametrised35presentations; these are parametrised presentations as defined by Eick36and Leedham-Green \cite{ELG08} and additionally they have various features37of polycyclic presentations. Each such presentation defines all the38infinitely many finite $p$-groups in an infinite coclass sequence.3940We then provide some algorithms to compute with polycyclic parametrised41presentations. In particular, we introduce a generalisation of the42collection algorithm for polycyclic parametrised presentations. Based43on this, we describe algorithms to compute polycyclic parametrised44presentations for Schur extensions, for the Schur multiplicator and45for some low-dimensional cohomology groups. We refer to \cite{EF11}46for details on the underlying algorithms and further references.4748Finally, we exhibit a database of polycyclic parametrised presentations49for the infinite coclass families of the finite $2$-groups of coclass at50most $2$ and the finite $3$-groups of coclass $1$.5152%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%53\Section{Background on (polycyclic) parametrised presentations}5455In this section we describe the polycyclic parametrised presentations56(pp-presentations) for infinite coclass sequences.5758Let $(G_x | x\in \N)$, where $\N$ denotes the natural numbers, be an59infinite coclass sequence; $x$ is the parameter of this infinite coclass60sequence. Then every group $G_x$ is an extension of a finite $p$-group $P$61of order $p^n$ by an abelian $p$-group $T_x$ of rank $d$. Furthermore, every62$G_x$ has a polycyclic presentation (short pp-presentation) on generators63$g_1, \ldots, g_n, t_1, \ldots, t_d$ with relations of the form64%display{nontext}65$$66\eqalign{67&g_i^{p} = g_{i+1}^{a_{i,i,i+1}} \cdots g_n^{a_{i,i,n}}t_1^{\alpha_{i,i,1}(x)} \cdots t_d^{\alpha_{i,i,d}(x)}, \cr68&g_i^{g_j} = g_{j+1}^{a_{i,j,j+1}} \cdots g_n^{a_{i,j,n}}t_1^{\alpha_{i,j,1}(x)} \cdots t_d^{\alpha_{i,j,d}(x)}, \cr69&t_k^{g_i} = t_1^{b_{k,i,1}(x)} \cdots t_d^{b_{k,i,d}(x)}, \cr70&t_k^{t_l} = t_k, \cr71&t_k^{p^{x+e}} = 1,72}73$$74%display{text}75%g_i^p = g_{i+1}^{a_{i,i,i+1}} ... g_n^{a_{i,i,n}}t_1^{\alpha_{i,i,1}(x)}... t_d^{\alpha_{i,i,d}(x)},76%g_i^{g_j} = g_{j+1}^{a_{i,j,j+1}} ... g_n^{a_{i,j,n}}t_1^{\alpha_{i,j,1}(x)}... t_d^{\alpha_{i,j,d}(x)},77%t_k^{g_i} = t_1^{b_{k,i,1}(x)}... t_d^{b_{k,i,d}(x)},78%t_k^{t_l} = t_k,79%t_k^{p^{x+e}} = 1,80%enddisplay81where $1\le j \< i\le n$ and $1 \le k \< l\le d$; certain $a_{i,j,m}\in \{0,82\ldots, p-1\}$, a non-negative integer $e$, $\alpha_{k,l,m}(x)$ of the form83$c_{k,l,m}+p^xd_{k,l,m}$ and $b_{k,l,m}$ with $b_{k,l,m},c_{k,l,m},d_{k,l,m}$84certain $p$-adic integers. The $p$-adic exponents arising in the relations85can be reduced modulo the relative orders of the involved elements and thus86can be reduced to integers for every specific $x$.8788We call such a pp-presentation $integral$ if89all the $p$-adic numbers $b_{k,l,m}, c_{k,l,m}, d_{k,l,m}$ are integers.90Our algorithms introduced in this package compute with integral91pp-presentations only.9293We call such an pp-presentation $consistent$ if for every $x \in \N$94the presentation is consistent as a polycyclic presentation; where we95possibly reduce the exponents in the presentation modulo the relative96orders of the generators.9798%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%99\Section{Computation of Schur multiplicators}100101In this section we recall briefly the method of \cite{EF11} to determine102the Schur multiplicators of almost all groups $G_x$ in an infinite coclass103sequence.104105Suppose we are given a consistent integral pp-presentation $F/R_x$ for the106groups $G_x$ in an infinite coclass sequence, where $F$ is a free group and107$R_x$ is generated by parametrised relations as above. Note that the108exponents in these relations depend on $x$, while the number of generators109and the number of relations does not depend on the parameter.110111Using this presentation we can define a parametrised presentation for the112Schur extensions $G_x^{*} = F/[F,R_x]$, corresponding to the parametrised113presentation $F/R_x$. The next step is to find the isomorphism types of114$Y_x = R_x/[F,R_x]$ since $M(G_x) \cong (F^\prime \cap R_x)/[F,R_x]$ are the115torsion subgroups of $Y_x$ as all $G_x$ are finite <p>-groups.116117Then $Y_x = R_x/[F,R_x]$ are generated by certain so-called118consistency relations. Using this we can compute the isomorphism types of119$Y_x$ and thus the isomorphism types of $M(G_x)$ for almost all $G_x$ in the120chosen infinite coclass sequence.121122%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%123\Section{Computation of low-dimensional cohomology}124125From the parametrised presentation $F/R_x$ we can see that the Abelian126invariants are the same for all groups $G_x$ in an infinite coclass sequence,127and we can compute them. Using this and the computation of the Schur128multiplicators one obtains $H^n(G_x,\Z)$ and $H^n(G_x,GF(p))$ for $0 \le n129\le 2$, where the $G_x$ act trivially on $\Z$ and $GF(p)$, respectively.130131%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%132\Section{Example}133134In this section we present the well-known example of quaternion groups135$Q_{2^{x+3}}$. It is well known that they have a parametrised presentation of136the following form:137138%display{nontext}139$$140\eqalign{141\{ g_1,g_2,t_1 | &\, g_1^{2} = t_1^{2^x}, \, g_2^{g_1} = g_2t_1^{-1+2^{x+1}},\cr142&\, g_2^{2} = t_1, \, t_1^{g_1} = t_1^{-1+2^{x+1}},\cr143&\, t_1^{2^{x+1}} = 1 \}.144}145$$146%display{text}147% { g_1,g_2,t_1|g_1^2 = t_1^{2^x}, g_2^{g_1} = g_2t_1^{-1+2^{x+1}},148% g_2^{2} = t_1, t_1^{g_1} = t_1^{-1+2^{x+1}},149% t_1^{2^{x+1}} = 1 }.150%enddisplay151152Using this we can define the Schur extensions $Q_{2^{x+3}}^{*}$153154%display{nontext}155$$156\eqalign{157\{ g_1,g_2,t_1,c_1, c_2, c_3 | &g_1^{2} = t_1^{2^x}c_3,158\, g_2^{g_1} = g_2t_1^{-1+2^{x+1}}c_2^{1-2^{x+1}},\cr159&\, g_2^{2} = t_1c_1,\, t_1^{g_1} = t_1^{-1+2^{x+1}}c_2^{2-2^{x+1}},\cr160&\, t_1^{2^{x+1}} = c_2^{2^{x+1}}, \cr161&\, c_1,c_2,c_3 central \}.162}163$$164%display{text}165% { g_1,g_2,t_1,c_1,c_2,c_3|g_1^{2} = t_1^{2^x}c_3,166% g_2^{g_1} = g_2t_1^{-1+2^{x+1}} c_2^{1-2^{x+1}},167% g_2^{2} = t_1c_1,168% t_1^{g_1} = t_1^{-1+2^{x+1}} c_2^{2-2^{x+1}},169% t_1^{2^{x+1}} = c_2^{2^{x+1}},170% c_1,c_2,c_3 central }.171%enddisplay172173This yields $M(Q_{2^{x+3}}) = 1$.174175176